CN216318011U - Intelligent heart regulation and measurement analyzer - Google Patents

Abstract

The utility model discloses an intelligent heart adjusting and measuring analyzer, which comprises a body, a supporting plate arranged in the body, a plurality of fixed blocks arranged at two ends of the bottom in the body, a buffer component arranged in the fixed blocks, a connecting component arranged at the bottom of the supporting plate and matched with the buffer component, and a plurality of damping components arranged at the bottom of the body, the damping part comprises two supporting blocks arranged at the bottom of the body, a sliding rod arranged between the supporting blocks, a sliding block arranged on the sliding rod and a first spring arranged on one side surface of the sliding block, the other end of the first spring is connected with one side surface of the supporting block, the fixed block is fixedly connected with the sliding rod, the medical device has the advantages of being resistant to falling, and the problem that rescue opportunity of a patient is affected due to the fact that equipment falls down and is damaged due to collision of the equipment caused by accidental collision when medical equipment is used in the prior art is solved.

Description

Intelligent heart regulation and measurement analyzer

Technical Field

The utility model belongs to the technical field of medical equipment, and particularly relates to an intelligent heart debugging analyzer.

Background

With the pace of life, the population pressure and the aging of the mouth of people in the modern society, more and more patients with cardiovascular and cerebrovascular diseases are caused, and the cardiovascular and cerebrovascular diseases are common diseases seriously threatening the health of human beings, especially the health of middle-aged and elderly people over 50 years old, and have the characteristics of high morbidity, high disability rate and high mortality rate; the problems existing in the prior art are as follows: accidental collision can occur when medical equipment is used, so that the equipment falls off, the equipment is damaged due to collision, and the rescue opportunity of a patient is influenced.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems in the prior art, the utility model provides an intelligent heart regulation and measurement analyzer which has the advantage of falling resistance and solves the problem that the rescue opportunity of a patient is influenced because the equipment falls due to accidental collision when medical equipment is used and the equipment is damaged due to collision of the equipment.

The utility model is realized in such a way that the heart intelligent debugging analyzer comprises a body, a supporting plate arranged in the body, a plurality of fixed blocks arranged at two ends of the bottom in the body, a buffer component arranged in the fixed blocks, a connecting component arranged at the bottom of the supporting plate and matched with the buffer component, and a plurality of damping components arranged at the bottom of the body, wherein each damping component comprises two supporting blocks arranged at the bottom of the body, a sliding rod arranged between the supporting blocks, a sliding block arranged on the sliding rod, and a first spring arranged on one side surface of the sliding block, the other end of the first spring is connected with one side surface of the supporting block, the fixed blocks are fixedly connected with the sliding rod, and the sliding block is in sliding connection with the sliding rod.

Preferably, the connecting member includes a transmission block disposed at the bottom of the support plate, a first rotating shaft disposed at the bottom of the transmission block, a transmission plate disposed at the bottom of the first rotating shaft, and a second rotating shaft disposed at the bottom of the transmission plate, and the second rotating shaft is rotatably connected to the sliding block.

Preferably, the buffer member includes a telescopic slot disposed at the top of the fixed block, a limiting slot disposed at the bottom of the telescopic slot, a telescopic rod disposed at the bottom of the supporting plate, a limiting plate disposed at the bottom of the telescopic rod, and a second spring disposed at the bottom of the limiting plate, the bottom of the second spring is connected to the bottom of the limiting slot, the telescopic rod is connected to the telescopic slot and extends into the limiting slot, and the diameter of the limiting slot is greater than that of the telescopic slot.

Preferably, the bottom of the limiting groove is provided with a stabilizing bar, the telescopic rod is internally provided with a stabilizing groove matched with the stabilizing bar, and the stabilizing bar is connected with the stabilizing groove and extends into the stabilizing groove.

Preferably, the two side walls of the body are provided with heat dissipation grooves, the bottom of each heat dissipation groove is provided with an accumulation groove, the bottom of each heat dissipation groove is provided with a first filter plate, the top of each accumulation groove is provided with a second filter plate, the first filter plates are connected with the second filter plates, and the first filter plates and the second filter plates are obliquely arranged.

Preferably, a stabilizing plate for preventing the sliding block from rotating to both sides is provided under the sliding rod, and both ends of the stabilizing plate are connected to a sidewall of the supporting block.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, by arranging the supporting block, the sliding rod, the sliding block and the first spring, the sliding block can move to one side on the sliding rod supported by the supporting block when being stressed, so that the first spring is driven to contract, and the damping effect is achieved.

According to the utility model, through arranging the transmission block, the first rotating shaft, the transmission plate and the second rotating shaft, the transmission block is stressed to transmit force to the sliding block through the first rotating shaft, the transmission plate and the second rotating shaft in sequence, so that the effect of transmission force is achieved.

According to the utility model, by arranging the telescopic groove, the limiting groove, the telescopic rod, the limiting plate and the second spring, the supporting plate can drive the telescopic rod to move downwards in the telescopic groove and the limiting groove when being stressed downwards, then the second spring contracts to play a role in buffering, and the limiting plate plays a role in preventing the telescopic rod from moving upwards excessively when the telescopic rod is reset.

According to the utility model, by arranging the stabilizer bar and the stabilizing groove, the stabilizer bar can enter the stabilizing groove when the telescopic rod moves downwards, and the function of preventing the stabilizer bar from shaking is achieved.

According to the utility model, through the arrangement of the heat dissipation groove, the accumulation groove, the first filter plate and the second filter plate, dust in air can be filtered by the first filter plate and the second filter plate when air outside the body enters the body, and the accumulation groove plays a role in accumulating dust and preventing dust from scattering.

According to the utility model, the stabilizing plate is arranged, so that the sliding block can be prevented from shaking due to uneven stress when the sliding block moves to one side.

Drawings

FIG. 1 is a schematic diagram of a structure provided by an embodiment of the present invention;

FIG. 2 is a left side view provided by an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken at A-A in accordance with an embodiment of the present invention;

FIG. 4 is an enlarged view at A of FIG. 3 provided by an embodiment of the present invention;

fig. 5 is an enlarged view of B in fig. 3 according to an embodiment of the present invention.

In the figure: 1. a body; 11. a support plate; 12. a fixed block; 13. a support block; 14. a slide bar; 15. a slider; 16. a first spring; 21. a transfer block; 22. a first rotating shaft; 23. a transfer plate; 24. a second rotating shaft; 31. a telescopic groove; 32. a limiting groove; 33. a telescopic rod; 34. a limiting plate; 35. a second spring; 41. a stabilizer bar; 42. a stabilizing slot; 51. a heat sink; 52. a stacking tank; 53. a first filter plate; 54. a second filter plate; 61. and a stabilizing plate.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following embodiments are illustrated and described in detail with reference to the accompanying drawings.

The structure of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1 to 5, an intelligent heart testing analyzer according to an embodiment of the present invention includes a body 1, a supporting plate 11 disposed in the body 1, a plurality of fixing blocks 12 disposed at two ends of a bottom of the body 1, a buffer component disposed in the fixing blocks 12, a connecting component disposed at the bottom of the supporting plate 11 and matched with the buffer component, and a plurality of shock absorbing components disposed at the bottom of the body 1, where the shock absorbing components include two supporting blocks 13 disposed at the bottom of the body 1, a sliding rod 14 disposed between the supporting blocks 13, a sliding block 15 disposed on the sliding rod 14, and a first spring 16 disposed on one side of the sliding block 15, where another end of the first spring 16 is connected to one side of the sliding block 13, the fixing block 12 is fixedly connected to the sliding rod 14, and the sliding block 15 is slidably connected to the sliding rod 14.

Referring to fig. 3, the connecting member includes a transmission block 21 disposed at the bottom of the support plate 11, a first rotating shaft 22 disposed at the bottom of the transmission block 21, a transmission plate 23 disposed at the bottom of the first rotating shaft 22, and a second rotating shaft 24 disposed at the bottom of the transmission plate 23, and the second rotating shaft 24 is rotatably connected to the sliding block 15.

Adopt above-mentioned scheme: by providing the transmission block 21, the first rotating shaft 22, the transmission plate 23, and the second rotating shaft 24, the transmission block 21 is forced to transmit the force to the slide block 15 through the first rotating shaft 22, the transmission plate 23, and the second rotating shaft 24 in this order, thereby exerting the transmission force.

Referring to fig. 4, the buffer member includes a telescopic slot 31 disposed at the top of the fixing block 12, a limiting slot 32 disposed at the bottom of the telescopic slot 31, a telescopic rod 33 disposed at the bottom of the supporting plate 11, a limiting plate 34 disposed at the bottom of the telescopic rod 33, and a second spring 35 disposed at the bottom of the limiting plate 34, wherein the bottom of the second spring 35 is connected to the bottom of the limiting slot 32, the telescopic rod 33 is connected to the telescopic slot 31 and extends into the limiting slot 32, and the diameter of the limiting slot 32 is greater than that of the telescopic slot 31.

Adopt above-mentioned scheme: through setting up flexible groove 31, restriction groove 32, telescopic link 33, limiting plate 34 and second spring 35, can make backup pad 11 atress drive telescopic link 33 and move down in flexible groove 31 and restriction groove 32, then second spring 35 contracts, has played the effect of buffering, and limiting plate 34 has played the effect that prevents the excessive upward movement of telescopic link 33 when telescopic link 33 resets.

Referring to fig. 4, a stabilizer bar 41 is disposed at the bottom of the restriction groove 32, a stabilizing groove 42 is disposed in the extension rod 33 and is matched with the stabilizer bar 41, and the stabilizer bar 41 is connected with the stabilizing groove 42 and extends into the stabilizing groove 42.

Adopt above-mentioned scheme: by providing the stabilizer bar 41 and the stabilizer groove 42, the stabilizer bar 41 can be inserted into the stabilizer groove 42 when the telescopic rod 33 moves downward, thereby preventing the stabilizer bar 41 from shaking.

Referring to fig. 5, the two side walls of the body 1 are provided with heat dissipation grooves 51, the bottom of each heat dissipation groove 51 is provided with a stacking groove 52, the bottom of each heat dissipation groove 51 is provided with a first filter plate 53, the top of each stacking groove 52 is provided with a second filter plate 54, the first filter plates 53 are connected with the second filter plates 54, and the first filter plates 53 and the second filter plates 54 are inclined.

Adopt above-mentioned scheme: through setting up radiating groove 51, piling up groove 52, first filter 53 and second filter 54, can make body 1 outside gas get into can be filtered the dust in the air by first filter 53 and second filter 54 when body 1, pile up groove 52 and played the effect of piling up the dust, played the effect that prevents the dust scattered all around.

Referring to fig. 3, a stabilizing plate 61 for preventing the sliding block 15 from rotating to both sides is provided under the sliding rod 14, and both ends of the stabilizing plate 61 are connected to one sidewall of the supporting block 13.

Adopt above-mentioned scheme: by providing the stabilizing plate 61, the slide block 15 can be prevented from wobbling due to uneven force applied to the slide block 15 when the slide block 15 is moved to one side.

The working principle of the utility model is as follows: when the device is used, after the body 1 falls, the device which is positioned in the body 1 and positioned at the top of the support plate 11 can enable the support plate 11 to move downwards, the support plate 11 moves downwards to drive the transmission block 21 to move downwards, the force applied to the transmission block 21 is transmitted to the sliding block 15 through the first rotating shaft 22, the transmission plate 23 and the second rotating shaft 24, the force applied to the sliding block 15 moves to one side, then the first spring 16 contracts to play a role in shock absorption, the sliding block 15 shakes due to uneven stress when the sliding block 15 moves, the sliding block 15 can stably move by being contacted with the stabilizing plate 61 at the moment, the telescopic rod 33 also moves downwards when the support plate 11 descends, then the second spring 35 contracts, the stabilizing rod 41 enters the stabilizing groove 42 to play a role in buffering, when the device is in a safe operation state, the outside gas of body 1 will get into body 1 through radiating groove 51 in, the heat that equipment gave out simultaneously also can discharge outside body 1 through radiating groove 51, then the gas will contact with first filter 53 and second filter 54 when body 1 outside gas gets into body 1, the dust in the gas this moment will be filtered then get into and pile up the groove 52, then will not make steam direct and dust contact when equipment dispels the heat, prevent that the dust from scattering, played the effect that keeps the air clean.

In summary, the following steps: this heart intelligence investigation analysis appearance, the equipment that is in body 1 inside and is located 11 tops of backup pad through body 1 after dropping will make backup pad 11 downstream, backup pad 11 downstream drives transmission piece 21 downstream, the power that transmission piece 21 received this moment will be through first pivot 22, transmission piece 23 and 24 transmission of second pivot are for sliding block 15, sliding block 15 atress will be to a lateral shifting, then first spring 16 contracts, it can appear accidental collision when using medical equipment to have solved and lead to equipment to drop, lead to equipment to collide with and make equipment damage, thereby influence the problem of patient's rescue opportunity.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a heart intelligence is transferred and is surveyed analysis appearance, includes body (1), locate backup pad (11) in body (1), locate a plurality of fixed blocks (12) at bottom both ends in body (1), locate the buffer unit in fixed block (12), locate backup pad (11) bottom and buffer unit matched with adapting unit and locate a plurality of shock attenuation parts of body (1) bottom, its characterized in that: the damping part comprises two supporting blocks (13) arranged at the bottom of the body (1), a sliding rod (14) arranged between the supporting blocks (13), a sliding block (15) arranged on the sliding rod (14) and a first spring (16) arranged on one side face of the sliding block (15), the other end of the first spring (16) is connected with one side face of each supporting block (13), the fixed block (12) is fixedly connected with the sliding rod (14), and the sliding block (15) is connected with the sliding rod (14) in a sliding mode.

2. The intelligent cardiac conditioning analyzer of claim 1, wherein: the connecting part comprises a transmission block (21) arranged at the bottom of the support plate (11), a first rotating shaft (22) arranged at the bottom of the transmission block (21), a transmission plate (23) arranged at the bottom of the first rotating shaft (22) and a second rotating shaft (24) arranged at the bottom of the transmission plate (23), and the second rotating shaft (24) is rotatably connected with the sliding block (15).

3. The intelligent cardiac conditioning analyzer of claim 1, wherein: buffer unit is including locating flexible groove (31) at fixed block (12) top, locating restriction groove (32) of flexible groove (31) bottom, locating telescopic link (33) of backup pad (11) bottom, locating restriction board (34) of telescopic link (33) bottom and locating second spring (35) of restriction board (34) bottom, second spring (35) bottom is connected with restriction groove (32) bottom, telescopic link (33) are connected with flexible groove (31) and are extended to in restriction groove (32), the diameter in restriction groove (32) is greater than the diameter in flexible groove (31).

4. The intelligent cardiac conditioning analyzer of claim 3, wherein: the bottom of the limiting groove (32) is provided with a stabilizing rod (41), a stabilizing groove (42) matched with the stabilizing rod (41) is arranged in the telescopic rod (33), and the stabilizing rod (41) is connected with the stabilizing groove (42) and extends into the stabilizing groove (42).

5. The intelligent cardiac conditioning analyzer of claim 1, wherein: be equipped with radiating groove (51) on body (1) both sides wall, radiating groove (51) bottom is equipped with piles up groove (52), radiating groove (51) bottom is equipped with first filter (53), it is equipped with second filter (54) to pile up groove (52) top, first filter (53) are connected with second filter (54), first filter (53) all incline to set up with second filter (54).

6. The intelligent cardiac conditioning analyzer of claim 1, wherein: and a stabilizing plate (61) for preventing the sliding block (15) from rotating towards two sides is arranged below the sliding rod (14), and two ends of the stabilizing plate (61) are connected with one side wall of the supporting block (13).

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